Transport and conservation laws

%M. Lüscher; B. S. Shastry; B. Sutherland; E. Olmedilla; F. H. L. Essler; F. Naef; G. Jona-Lasinio; H. B. Thacker; H. Castella; H. Castella; M. G. Tetel'man; M. P. Grabowski; M. Suzuki; P. Mazur; P. P. Kulish; P. Prelovsek; R. Kubo; W. F. Brinkman; W. Kohn; X. Zotos; X. Zotos

research

Transport and conservation laws

Authors: %M. Lüscher
B. S. Shastry
B. Sutherland
E. Olmedilla
F. H. L. Essler
F. Naef
G. Jona-Lasinio
H. B. Thacker
H. Castella
H. Castella
M. G. Tetel'man
M. P. Grabowski
M. Suzuki
P. Mazur
P. P. Kulish
P. Prelovsek
R. Kubo
W. F. Brinkman
W. Kohn
X. Zotos
X. Zotos
Publication date: 1 November 1996
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We study the lowest order conservation laws in one-dimensional (1D) integrable quantum many-body models (IQM) as the Heisenberg spin 1/2 chain, the Hubbard and t-J model. We show that the energy current is closely related to the first conservation law in these models and therefore the thermal transport coefficients are anomalous. Using an inequality on the time decay of current correlations we show how the existence of conserved quantities implies a finite charge stiffness (weight of the zero frequency component of the conductivity) and so ideal conductivity at finite temperatures.Comment: 6 pages, Late

Similar works

Full text

Available Versions

Crossref

Last time updated on 03/01/2020